Method for accelerated break out of connected multi-segment tubulars

ABSTRACT

A method for accelerated break out of connected multi-segment tubulars by setting hydraulic fluid pressure to between 100 and 3000 psi, connecting the stationary wrench to a first segment of a multi-segment tubular, connecting a pivoting wrench to a second segment of the multi-segment tubular, and activating a pivoting hydraulic cylinder with a lever to break out the first segment from the second segment and wherein the pivoting wrench is configured to operate right side up and upside down for optimizing pivoting wrench flat fit.

The present application is a Continuation In Part of U.S. patent Ser.No. 15/809,283 filed on Nov. 10, 2017, for “Accelerated Rod and SinkerBar Break Out Device” which claims priority to U.S. Provisional PatentApplication Ser. No. 62/448,915, filed on Jan. 20, 2017, for“Accelerated Rod and Sinker Bar Break Out Device.” These references arehereby incorporated in their entirety.

FIELD

The present embodiments generally relate to a method for acceleratedbreak out of connected multi-segment tubulars.

BACKGROUND

A need exists for a fast, easy to use method that can be used at groundlevel or elevated above a well head to break out a first segment of aconnected multi-segment tubular from a second segment of the connectedmulti-segment tubular, preventing injury or death to oilfield hands andworkers.

The present embodiments meet these needs.

BRIEF DESCRIPTION OF THE DRAWINGS

The detailed description will be better understood in conjunction withthe accompanying drawings as follows:

FIG. 1 depicts a top view of the device according to one or moreembodiments of the method.

FIG. 2 depicts a side view of the device according to one or moreembodiments of the method.

FIG. 3 depicts a top view of the device with a cylinder rod of apivoting hydraulic cylinder extended according to one or moreembodiments of the method.

FIG. 4 shows the pivoting movement of the pivoting hydraulic cylinderaccording to one or more embodiments of the method.

FIG. 5 shows a detail of a pivoting wrench according to one or moreembodiments of the method.

FIG. 6 is a diagram of the flow of hydraulic fluid according to one ormore embodiments.

FIG. 7 is a detail of a client device according to one or moreembodiments of the method.

FIG. 8 is a detail of a microprocessor according to one or moreembodiments of the method.

FIG. 9A-9E depict another embodiment of the device according to one ormore embodiments of the method.

FIG. 10A-B depicts an exemplary method according to one or moreembodiments.

FIG. 11A-B depicts an exemplary method according to one or moreembodiments.

The present embodiments are detailed below with reference to the listedFigures.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Before explaining the present method in detail, it is to be understoodthat the method is not limited to the particular embodiments and that itcan be practiced or carried out in various ways.

The present embodiments relate to a method for accelerated break out ofconnected multi-segment tubulars.

The invention can relate to a method for an accelerated rod and sinkerbar break out for rods and sinker bars involves extending from awellbore includes elevating an accelerated rod and sinker bar break outdevice above a wellbore using a support.

The method involves using an accelerated rod and sinker bar break outdevice with a support beam mounted in parallel to the pivoting hydrauliccylinder to prevent collapse of the base.

In a first embodiment, the method for accelerated break out of connectedmulti-segment tubulars uses an accelerated rod and sinker bar break outdevice with a support beam mounted in parallel to an installed pivotinghydraulic cylinder to prevent collapse of a base of the accelerated rodand sinker bar break out device.

The next step of this method involves setting hydraulic fluid pressurein the accelerated rod and sinker bar break out device to between 100and 3000 psi.

Next, the method continues by connecting a stationary wrench of theaccelerated rod and sinker bar break out device to a first segment of aconnected multi-segment tubular.

The method includes the step of connecting a pivoting wrench of theaccelerated rod and sinker bar break out device to a second segment ofthe connected multi-segment tubular.

Finally, in this version of the method, a pivoting hydraulic cylinder ofthe accelerated rod and sinker bar break out device is activated using alever to break out the first segment from the second segment.

In this method the pivoting wrench is configured to operate right sideup and upside down for optimizing pivoting wrench flat fit.

It should be noted that the stationary wrench extends at an angle of 90degrees to a plane of the base.

Embodiments of the method contemplate using an angled wrench head and apivoting wrench arm as the pivoting wrench.

Embodiments of the method use an active radio frequency identificationchip for tracking a GPS location of each accelerated rod and sinker barbreak out device when deployed, and wherein the radio frequencyidentification chip communicates via a network to at least one clientdevice having a client device display and a client device processorcommunicating with computer instructions in a client device data storageinstructing the client device processor to position the GPS location ofthe accelerated rod and sinker bar break out device geographically on amap.

Further embodiments of the method contemplate using a microprocessorconnected to at least one pressure sensor for automatically monitoringand comparing detected pressures to preset limits stored in amicroprocessor data storage, and computer instructions for instructingthe microprocessor to provide an alarm to the client device processorvia the network when the pressure falls below or exceeds the presetlimits.

The method involves as an option using a hydraulic pressure from 100 psito 3000 psi in a manifold mounted to the accelerated rod and sinker barbreak out device.

The method includes as an option using a pivoting wrench and astationary wrench each having a thickness from ½ of an inch to 1 inch.

In this method a pivoting wrench and the stationary wrench can be usedmade from a hardened high tensile strength solid steel hardened to aRockwell 55 hardness, wherein each wrench is a pipe wrench.

The length of each wrench can vary, and in this method a pivoting wrenchand a stationary wrench, each having a length from 18 inches to 48inches can be utilized.

In versions of the method, a pivoting wrench can have a head with alength different than the head of the stationary wrench.

Other embodiments of the method contemplate using a pivoting wrench withan arm having a length different than an arm of the stationary wrench.

Finally, the method can involve using a stationary wrench with a hookshape to hold the accelerated rod and sinker bar break out device stableas the pivoting wrench head is attached to the wrench flats of theconnected multi-segment tubulars.

A different embodiment of the method method for accelerated break out ofconnected multi-segment tubulars, contemplates receiving hydraulic fluidfrom a reservoir through an input port fluidly to a pivoting hydrauliccylinder.

Next, this version of the method involves transferring the hydraulicfluid to the reservoir an output port from the pivoting hydrauliccylinder.

Bidirectionally hydraulic fluid can be passed to and from the firstpivoting hydraulic cylinder port through a first bidirectional controlport to and from the pivoting hydraulic cylinder.

Bidirectionally hydraulic fluid can be passed to and from the secondpivoting hydraulic cylinder port through a second bidirectional controlport to and from the pivoting hydraulic cylinder.

In this version of the method, a lever can be used to engage a manifoldto change hydraulic fluid flow rates to and from the pivoting hydrauliccylinder and then a primary pressure control valve can be activated toadjust hydraulic fluid pressure to and from the pivoting hydrauliccylinder.

In this method, a pivoting wrench is affixed to a first segment of aconnected multi-segment tubular, and a stationary wrench is affixed to asecond segment of a connected multi-segment tubular.

Finally, the pivoting hydraulic cylinder is operated to flow hydraulicfluid moving the pivoting hydraulic cylinder to break out the firstsegment of a connected multi-segment tubular from the second segment ofa connected multi-segment tubular.

This version of the method involves using a flexible hanger and levelingdevice for stabilizing the equipment as the method is implemented. Theflexible hanger and leveling device has a pair of slotted plates mountedin parallel on a top side of a housing holding components of the deviceand; a leveling screw installed through slots of the pair of slottedplates; and a shackle moveably mounted around the leveling screw.

Similarly, this version of the method involves using a wrench stop tocontrol pivoting of the wrenches to within a preset limit.

Finally, this version of the method contemplates using a latching headconnected to a cylinder rod of the pivoting hydraulic cylinder and usingthe pivoting wrench enabling adjustment of the pivoting wrench to adjusta location of the second segment of a connected multi-segment tubularsegment.

The accelerated rod and sinker bar break out device can be used on rodsand sinker bars extending from a wellbore.

The accelerated rod and sinker bar break out device can have a base witha base support.

The base can be a flat metal plate, a lidless metal box, a speciallyshaped plate.

A plurality of flexible hanging devices can be attached to the base. Inembodiments, the flexible handing devices can be chain.

The flexible hanging devices can be removably connected to the baseenabling hoisting of the accelerated rod and sinker bar break outdevice.

A pivoting hydraulic cylinder can be connected to the base support on afirst end.

The pivoting hydraulic cylinder can have a cylinder rod, a firstpivoting hydraulic cylinder port, and a second pivoting hydrauliccylinder port. The ports can bidirectionally receive or expel hydraulicfluid.

In embodiments, a first pin can connect the pivoting hydraulic cylinderto the base support, maintaining the pivoting hydraulic cylinder abovethe base.

A pivoting wrench can connect to a cylinder rod of the pivotinghydraulic cylinder or a first end. The pivoting wrench can have wrenchflats for grabbing at wrench fiats on a rod or sinker bar.

A second pin can connect the pivoting wrench to the pivoting hydrauliccylinder.

The wrench flats of the pivoting wrench can be formed at a 45 degreeangle to the second pin.

In embodiments, the device can have a stationary wrench connected to thebase, which can have a hook shape.

The stationary wrench can have an arm connected to a cylinder rodclevis. The cylinder rod clevis can engage the rod or sinker bar wrenchflats.

The arm of the stationary wrench can extend at an angle, such as 90degrees, to a plane of the base. The head of the stationary wrench canbe configured for engaging a wrench flat formed on the rod or sinker barextending from a wellbore.

In embodiments, the accelerated rod and sinker bar break out device caninclude a hydraulic control assembly mounted to the base.

In embodiments, the accelerated rod and sinker bar break out device isportable, movable, and relocatable. In embodiments, the accelerated rodand sinker bar break out device can weigh from 50 pounds to 150 pounds.

In embodiments, the hydraulic control assembly can have a manifold. Themanifold can have a first pivoting hydraulic cylinder inlet port forreceiving hydraulic fluid from a reservoir and a second pivotinghydraulic cylinder output port for transferring hydraulic fluid to thereservoir.

The manifold can have a first bidirectional control port tobidirectionally flow hydraulic fluid to and from a first pivotinghydraulic cylinder port and a second bidirectional control port tobidirectionally flow hydraulic fluid to and from the second pivotinghydraulic cylinder port.

The accelerated rod and sinker bar break out device can have a leverengaging a manifold rod, which can be mounted in the manifold, forchanging hydraulic fluid flow rates to and from the pivoting hydrauliccylinder.

The device can have a primary pressure control valve to adjust hydraulicfluid pressure to the pivoting hydraulic cylinder.

The accelerated rod and sinker bar break out device can be elevatedenabling rod break out at an elevation from a top of a wellhead to 35feet above the wellhead.

The pivoting wrench and the pivoting hydraulic cylinder cansimultaneously pivot to engage a wrench flat on rods and sinker bars tobreak out the rods and sinker bars.

The pivoting wrench can be configured to operate right side up andupside down for optimizing pivoting wrench flat fit.

In embodiments, the accelerated rod and sinker bar break out device canhave an active radio frequency identification chip, which can be securedto the base for tracking a GPS location of each accelerated rod andsinker bar break out device when deployed.

The radio frequency identification chip can communicate via a network toa client device, which can have a client device display and a clientdevice processor.

The client device data storage can have computer instructions forinstructing the client device processor to position the GPS location ofthe accelerated rod and sinker bar break out device geographically on amap.

In embodiments, the accelerated rod and sinker bar break out device canhave a microprocessor, which can be connected to a plurality of pressuresensors for automatically monitoring and comparing detected pressures topreset limits stored in a microprocessor data storage.

The microprocessor data storage can contains computer instructions forinstructing the microprocessor to provide an alarm to a client deviceprocessor via the network when the pressure falls below or exceeds thepreset limits.

In embodiments, a support beam can be mourned parallel to the pivotinghydraulic cylinder to prevent collapse of the base.

In embodiments, the hydraulic pressure of the hydraulic fluid in themanifold can be from 100 psi to 3000 psi.

In embodiments, the pivoting wrench and the stationary wrench can eachhave a thickness from ½ inch to 1 inch.

In embodiments, the pivoting wrench and the stationary wrench can eachbe made from a hardened high tensile strength solid steel that has beenhardened to a Rockwell 55 hardness.

In embodiments, the pivoting wrench and the stationary wrench can eachhave a length from 4 inches to 12 inches.

In embodiments, the pivoting wrench can have a head with a lengthdifferent than the head of the stationary wrench.

In embodiments, the pivoting wrench arm can have an arm length differentthan the stationary wrench arm length.

In embodiments, the stationary wrench can have a hook shape to hold theaccelerated rod and sinker bar break out device stable as the pivotingwrench head is attached to the wrench flats of rods and sinker barsbeing broke out.

The term “break out’ as used herein refers to loosen a tight connectionbetween the rods that are screwed together, so that the connection canbe unscrewed by hand. Rods are not being “broken” during break out, athreaded connection is simply loosened.

The term “client device” as used herein can refer to any client deviceknown in the industry, such as a cellular phone, a laptop, a desktopcomputer, a tablet computer, a cloud based computer processor, or anydevice with bidirectional communication capabilities.

The term “data storage” refers to a non-transitory computer readablemedium, such as a hard disk drive, solid state drive, flash drive, tapedrive, and the like. The term “non-transitory computer readable medium”excludes any transitory signals but includes any non-transitory datastorage circuitry, e.g., buffers, cache, and queues, within transceiversof transitory signals.

The term “GPS” as used herein refers to a global positioning system.

The term “network” as used herein can refer any network known in theindustry, such as the internet, a local area network, a wide areanetwork, a satellite network, a cellular network or another type ofwireless network or combinations of networks.

The term “processor” as used herein can refer to any computer orprocessing device known in the industry, such as a programmable logiccircuit.

Turning now to the Figures, FIG. 1 depicts an accelerated rod and sinkerbar break out device according to one or more embodiments.

The accelerated rod and sinker bar break out device 8 can have a base 10with a base support 11.

In embodiments, the base support can extend from 2 inches to 10 inchesfrom the base.

The base can have a plane 88 on one side. The base can be suspended froma plurality of pad eyes 94 a-94 c using a plurality of flexible hangingdevices (not visible in this Figure.). The plurality of hanging devicescan be connected to the base enabling hoisting of the accelerated rodand sinker bar break out device.

The accelerated rod and sinker bar break out device can include apivoting hydraulic cylinder 14, which can be connected to the basesupport 11 on a first end 16.

The pivoting hydraulic cylinder can have a dimension of 3 and ½×12 inchstroke and be usable herein. The total length of the pivoting hydrauliccylinder with retracted cylinder rod between a first pin and a secondpin can be 22 and ¼ inch. The cylinder rod of the cylinder can extend 12more inches, providing a total length extended of 34 and ¼ inches.

The pivoting hydraulic cylinder can have a cylinder rod (shown in FIG.2), a first pivoting hydraulic cylinder port 18, and a second pivotinghydraulic cylinder port 19.

A first pin 21 can connect the first end 16 of the pivoting hydrauliccylinder 14 to the base support 11.

A pivoting wrench 30 with an angled wrench head 34 and a pivoting wrencharm 36 can connect to the cylinder rod.

The angled wrench head can have wrench flats 89 a-89 b for engagingwrench fiats on a rod or sinker bar.

A second pin 23 can connect the pivoting wrench 30 to the pivotinghydraulic cylinder 14.

The first and second pins can be solid cylinders of metal with twoperforations, wherein each perforation can be used for holding a cotterpin at each end.

A stationary wrench 50 can connect to the base 10, such as with aplurality of bolts.

The stationary wrench 50 can be a one piece unit with an integral arm 52connected to a head 54.

The arm 52 can extend at an angle 56, such as 90 degree angle, to theplane 86 of the base 10.

The head 54 of the stationary wrench can also be configured for engagingwrench flats formed on rods or sinker bars extending from the wellbore.

The cylinder rod is shown extending at a first distance 90 from thepivoting hydraulic cylinder 14. In embodiments, the first distance 90can be zero when the cylinder rod is in a fully retracted position.

The accelerated rod and sinker bar break out device can include ahydraulic control assembly 60, which can be mounted to the base 10.

The hydraulic control assembly 60 can have a manifold 62, The manifold62 can have an input port 64 for receiving hydraulic fluid 65 from areservoir and an output port 66 for transferring the hydraulic fluid 65to the reservoir.

The manifold 62 can have a first bidirectional control port 68 to flowthe hydraulic fluid 65 to and from the first pivoting hydraulic cylinderport 18.

The manifold 62 can have a second bidirectional control port 70 to flowthe hydraulic fluid 65 to and from the second pivoting hydrauliccylinder port 19.

The hydraulic control assembly 60 can have a lever 74, which can be usedfor engaging a manifold rod 72 in the manifold 62 for movably changinghydraulic fluid flow rates to and from the pivoting hydraulic cylinder14.

The hydraulic control assembly 60 can have a primary pressure controlvalve 80 to adjust hydraulic fluid pressure to and from the pivotinghydraulic cylinder 14, Usable pressure adjustment valves are availablefrom Parker Industries, of Texas.

In embodiments, a cylinder speed valve 75 can be used for controllingthe flow of the hydraulic fluid through the pivoting hydraulic cylinder14 in order to control the speed at which the cylinder rod moves backand forth in the pivoting hydraulic cylinder.

In embodiments, an active radio frequency identification chip 104 a canbe secured to the base 10 for tracking a GPS location of eachaccelerated rod and sinker bar break out device when deployed.

FIG. 2 depicts a side view of the accelerated rod and sinker bar breakout device according to one or more embodiments.

The plurality of flexible hanging devices 12 a-12 c can be connected tothe base 10 enabling hoisting of the accelerated rod and sinker barbreak out device.

In this embodiment, the flexible hanging devices are shown as chain. Thechain can be 4 foot long ¼ inch steel chain.

The pivoting wrench 30 can be connected to the cylinder rod 17 of thepivoting hydraulic cylinder 14 using the second pin 23.

The stationary wrench 50 can be connected to the base 10. The stationarywrench 50 is shown below the pivoting wrench 30 at a distance, such as 2inches and 9 inches, depending on the height of the base support 11.

The plurality of pad eyes 94 a-94 b can be used to support each of theplurality of flexible hanging devices 12 a-12 e.

The pivoting hydraulic cylinder 14 can have the cylinder rod 17extending from one end. The pivoting hydraulic cylinder can engage thebase support 11 on a side opposite the cylinder rod 17 using the firstpin 21.

The pivoting wrench 30 can engage the cylinder rod 17 with the secondpin 23.

The pivoting hydraulic cylinder 14 is shown with the first pivotinghydraulic cylinder port 18 and the second pivoting hydraulic cylinderport 19.

The lever 74 can engage the manifold rod of the manifold 61.

A support beam 206 can be mounted parallel to the pivoting hydrauliccylinder 14 to prevent collapse of the base.

An additional radio frequency identification chip 104 b is shown and canbe disposed on the support beam.

FIG. 3 depicts a top view of the accelerated rod and sinker bar breakout device with a cylinder rod of a pivoting hydraulic cylinder extendedaccording to one or more embodiments.

The accelerated rod and sinker bar break out device 8 is shown with thecylinder rod 17 extended from the pivoting hydraulic cylinder 14.

The accelerated rod and sinker bar break out device 8 is shown with thebase 10 supporting the pivoting hydraulic cylinder 14 extending thecylinder rod 17 at a second distance 92.

The pivoting wrench 30 is shown connected to the cylinder rod 17 by thesecond pin 23. The pivoting wrench 30 is shown with the angled wrenchhead 34 connected to the pivoting wrench arm 36.

The stationary wrench 50 is depicted with the head 54 connected to arm52.

The pivoting hydraulic cylinder 14 can be connected to the base supportwith the first pin 21.

The hydraulic control assembly 60 with the manifold 62 is shown.

FIG. 4 shows the pivoting movement of the pivoting hydraulic cylinderaccording to one or more embodiments.

The pivoting hydraulic cylinder 14 can be mounted to the base 10 usingthe base support with the first pin 21.

The pivoting hydraulic cylinder 14 can be pivoted through a first angle96 or a second angle 98 to allow an operator to easily move the pivotingwrench 30 into position. The first angle 96 can be from 0 degrees to 10degrees and the second angle 98 can be from 0 degrees to 25 degrees.

The hydraulic control assembly 60 can be mounted to the base 10, whichcan have a shape that is not rectangular and is angular. Many baseshapes can be used, such as triangles and octagons. The pivoting wrench30 with the angled wrench head 34 and the pivoting wrench arm 36 can beconnected to the cylinder rod via the second pin 23. The stationarywrench 50 with the head 54 and the arm 52 are also shown.

FIG. 5 shows a detail of a pivoting wrench according to one or moreembodiments.

The pivoting wrench 30 with the pivoting wrench arm 36 and the angledwrench head 34. The angled wrench head can be secured to a wrench flat76 a of a rod 78 a.

The stationary wrench 50 with the arm 52 and the head 54, wherein thehead 54 can be secured to a different wrench flat 76 b for a differentrod 78 b for break out of the rods.

FIG. 6 is a diagram of the flow of hydraulic fluid through theaccelerated rod and sinker bar break out device according to one or moreembodiments.

In this embodiment, a reservoir 300 can supply the hydraulic fluid 65 tothe input port 64 of the manifold 62 past a pressure sensor 108 a.

The pressure of the hydraulic fluid in the manifold 62 can he adjustedwith the primary pressure control valve 80.

The manifold rod 72 in the manifold 62 of the hydraulic control assemblycan be actuated by the lever 74. The manifold rod 72 controls thehydraulic fluid 65 through the first bidirectional control port 68 tothe first pivoting hydraulic cylinder port 18 to power the cylinder rodin the pivoting hydraulic cylinder 14.

The hydraulic fluid 65 can flow into the second bidirectional controlport 70 to and from the second pivoting hydraulic cylinder port 19.

A cylinder speed valve 75 can control the speed of the cylinder rod.

A pressure sensor 108 b can monitor pressure of the hydraulic fluid 65as it is returned to the reservoir 300 from the output port 66.

A microprocessor 106 can be in communication with the pressure sensors108 a-108 b and the primary pressure control valve 80 to communicateinformation to a network 99 and at least one client device 299 connectedto the network to control operations.

FIG. 7 is a detail of a client device according to one or moreembodiments.

At least one client device 299, which can have a client device display301 connected to a client device processor 302 and a client device datastorage 304 can be in communication with the network.

The client device data storage 304 can contain computer instructions 202for instructing the client device processor to position the GPS locationof the accelerated rod and sinker bar break out device geographically ona map.

In embodiments, the computer instructions can use a signal from theradio frequency identification chip. In embodiments the radio frequencyidentification chip can be in communication with the network, which canin turn communication to the at least one client device 299.

FIG. 8 is a detail of a microprocessor according to one or moreembodiments.

The microprocessor 106 can be connected to at least one pressure sensor(as shown in FIG. 6), or a plurality of pressure sensors, forautomatically detecting pressure of the hydraulic fluid in theaccelerated rod and sinker bar break out device.

The microprocessor can communicate with a microprocessor data storage110.

The microprocessor data storage 110 can have preset limits 112, such aspreset pressure limits for the hydraulic fluid in the pivoting hydrauliccylinder.

The microprocessor data storage 110 can contain computer instructions402 for instructing the microprocessor to provide an alarm to a clientdevice processor via the network when the hydraulic fluid pressure fallsbelow or exceeds the preset limits.

FIG. 9A-9E depict another embodiment of the invention.

FIG. 9A depicts an accelerated rod and sinker bar break out device 8 forrods and sinker bars extending from a wellbore.

The accelerated rod and sinker bar break out device 8 has a base 10 witha base support 11 rising from the base at a right angle and an extendedside 15 extending away from the base in the same plane as the base.

In embodiments, an integral one piece frame 13 can be connected to thebase 10 having are L shaped configuration. The integral one piece frame13 can be made of steel plate capable of sustaining pressures of 200 psiwithout deforming.

A flexible hanger and leveling device 112 is removably connected to theintegral one piece frame configured for supporting the accelerated rodand sinker bar break out device while hoisting.

The flexible hanger and leveling device 112 can be mounted to theportion of the integral one piece frame 13 opposite the base 10.

A pivoting hydraulic cylinder 14 can be mounted within the integral onepiece frame 13 and connects through the base support 11.

The pivoting hydraulic cylinder 14 can have a cylinder rod 17. Acylinder rod clevis 220 can be mounted to the cylinder rod 17.

In embodiments, a hydraulic control assembly 60 and the outlet port 116are shown.

FIG. 9B depicts an input port 100 for receiving hydraulic fluid from areservoir of a manifold of the hydraulic control assembly.

The integral one piece frame 13 and the hydraulic cylinder can be withinthe frame showing the second pivoting hydraulic cylinder port 19.

In embodiments, the first bidirectional control port 68 canbidirectionally flow the hydraulic fluid to and from the first pivotinghydraulic cylinder port 18. The second bidirectional control port 70 canbidirectionally flow the hydraulic fluid to and from the second pivotinghydraulic cylinder port.

The flexible hanger and leveling device 112 can have a pair of slottedplates 102 a and 102 b mounted in parallel on a top side of the onepiece frame 13. A leveling screw 132 can be mounted through the slots ofthe pair of slotted plates. A shackle 114 can be moveably positionedaround the leveling screw.

The leveling screw of the flexible hanger and leveling device 112 canhave a helical groove enabling the shackle to slide over the levelingscrew. The helical groove can be as wide as the shackle is wide. Allelements of the flexible hanger and leveling system can be made fromsteel.

In embodiments, a cylinder speed valve 75 can be used for controllingthe flow of the hydraulic fluid through the pivoting hydraulic cylinderin order to control the speed at which the cylinder rod moves back andforth in the pivoting hydraulic cylinder.

FIG. 9C depicts another view of this embodiment showing the integral onepiece frame 13.

A primary pressure control valve 80 shown, which can adjust hydraulicfluid pressure to the pivoting hydraulic cylinder.

A first pivoting hydraulic cylinder port 18 and a second pivotinghydraulic cylinder port 19 of the pivoting hydraulic cylinder 14 aredepicted.

Connected within the frame and through the frame is the pivotinghydraulic cylinder mounted over a bearing roller 118 that connects thepivoting hydraulic cylinder to the base.

Also within the integral one piece frame 13 can be a hydraulic controlassembly 60.

A lever 74 can engage the manifold 62 for changing hydraulic fluid flowrates to and from the pivoting hydraulic cylinder.

In embodiments, the accelerated rod and sinker bar break out device forrods and sinker bars can have a wrench stop 77 to control pivoting towithin a preset limit and a tool tray 120 providing protectedcontainerization of pivoting wrenches on the base.

FIGS. 9D and 9E depicts a pivoting wrench 30 that connects to thecylinder rod wherein the cylinder rod clevis engages a rod 78. Thepivoting wrench can have wrench fiats for a more secure engagement withthe rod 78.

A second pin 23 connects the pivoting wrench to the pivoting hydrauliccylinder 14, enabling the wrench fiats of the pivoting wrench to be atan angle to the second pin, such as at a 30 degree angle.

The pivoting wrench 30 and the pivoting wrench arm 36 can be connectedto the rod 78 via the second pin 23.

Separated from the pivoting wrench and attached to the base is astationary wrench 50.

The stationary wrench 50 connects to the base such as by rivets, orbolts and nuts.

Other fastening systems can be used which can sustain the torque neededto make up or break out the pipe.

In embodiments, a base lock 55 can be shown.

The stationary wrench can have an arm 52 connected to a head 54.

The arm can extend from the base in the same plane as the base and canbe oriented so that the head 54 has an opening that opens away from thebase.

The head can be configured for engaging a rod 78 extending from awellbore.

The opening of the head of the stationary wrench can be orientedopposite to the opening of the head 54 of the pivoting wrench 30 toprovide full torque to the pipe without twisting the device.

The hydraulic control assembly can have a plurality of components, allmounted within the integral one piece frame.

In embodiments, the accelerated rod and sinker bar break out device canuse a pivoting wrench 30 that has an angled wrench head and a pivotingwrench arm. The angled head can be 10 to 40 degrees angled from thelongitudinal axis of the wrench arm. The pivoting wrench arm can engagewith the pivoting hydraulic cylinder with removable pin or with alatching head 79 or both.

The tool tray 120 can be shown, providing protected containerization ofpivoting wrenches on the base.

In embodiments, the wrench stop 77 is depicted.

In this embodiment, the accelerated rod and sinker bar break out devicecan be elevated enabling rod break out at an elevation from a top of awellhead to 35 feet above the wellhead by handing from the flexiblehanger and leveling device, and wherein the pivoting wrench and thepivoting hydraulic cylinder can simultaneously pivot to engage rods andsinker bars from a wellbore to break out the rods and sinker bars. Thepivoting wrench is configured to operate right side up and upside downfor optimizing pivoting wrench flat fit.

As shown the accelerated rod and sinker bar break out device can have anactive radio frequency identification chip secured to the base fortracking a GPS location of each accelerated rod and sinker bar break outdevice when deployed, and wherein the radio frequency identificationchip communicates via a network to at least one client device having aclient device display and a client device processor communicating withcomputer instructions in a client device data storage instructing theclient device processor to position the GPS location of the acceleratedrod and sinker bar break out device geographically on a map and amicroprocessor connected to at least one pressure sensor forautomatically monitoring and comparing detected pressures to presetlimits stored in a microprocessor data storage, and computerinstructions for instructing the microprocessor to provide an alarm tothe client device processor via the network when the pressure fallsbelow or exceeds the preset limits.

In embodiments the accelerated rod and sinker bar break out device, thepivoting wrench and the stationary wrench each can have a length from 4inches to 12 inches.

In embodiments the accelerated rod and sinker bar break out device thepivoting wrench has a head with a length different than the head of thestationary wrench. In other embodiments, the pivoting wrench arm has alength different than the stationary wrench arm.

The invention contemplates that the accelerated rod and sinker bar breakout device uses a stationary wrench with a hook shape to hold theaccelerated rod and sinker bar break out device stable as the pivotingwrench head is attached to the wrench flats of rods and sinker barsbeing broke out.

In embodiments, the accelerated rod and sinker bar break out device forrods and sinker bars can have a latching head 79 connected to thecylinder rod and wherein the pivoting wrench enabling adjustment of thepivoting wrench to a location of the rod or sinker bar.

FIG. 10A-B depicts an exemplary method according to embodiments.

This Figure depicts the steps of the method for accelerated break out ofconnected multi-segment tubulars.

Box 1000 depicts the step of using an accelerated rod and sinker barbreak out device with a support beam mounted in parallel to an installedpivoting hydraulic cylinder to prevent collapse of a base of theaccelerated rod and sinker bar break out device.

Box 1001 depicts the step of using an active radio frequencyidentification chip for tracking a GPS location of each accelerated rodand sinker bar break out device when deployed, and wherein the radiofrequency identification chip communicates via a network to at least oneclient device having a client device display and a client deviceprocessor communicating with computer instructions in a client devicedata storage instructing the client device processor to position the GPSlocation of the accelerated rod and sinker bar break out devicegeographically on a map.

Box 1003 depicts the step of using a microprocessor connected to atleast one pressure sensor for automatically monitoring and comparingdetected pressures to preset limits stored in a microprocessor datastorage, and computer instructions for instructing the microprocessor toprovide an alarm to the client device processor via the network when thepressure falls below or exceeds the preset limits.

Box 1020 depicts the step of setting hydraulic fluid pressure in theaccelerated rod and sinker bar break out device to between 100 and 3000psi.

Box 1030 depicts the step of connecting a stationary wrench of theaccelerated rod and sinker bar break out device to a first segment of aconnected multi-segment tubular.

Box 1040 depicts the step of connecting a pivoting wrench of theaccelerated rod and sinker bar break out device to a second segment ofthe connected multi-segment tubular.

Box 1042 depicts the step of using a hydraulic pressure from 100 psi to3000 psi in a manifold mounted to the accelerated rod and sinker barbreak out device.

Box 1050 depicts the step of activating a pivoting hydraulic cylinder ofthe accelerated rod and sinker bar break out device using a lever tobreak out the first segment from the second segment, and wherein thepivoting wrench is configured to operate right side up and upside downfor optimizing pivoting wrench flat fit; and wherein the stationarywrench extends at an angle of 90 degrees to a plane of the base.

FIG. 11A-B depicts an exemplary method according to embodiments foraccelerated break out of connected multi-segment tubulars.

Box 1104 depicts the step of using a flexible hanger and leveling devicefor stabilizing the equipment of the method as the method is implementedusing a pair of slotted plates mounted in parallel on a top side of ahousing holding components utilized in the method and; a leveling screwinstalled through slots of the pair of slotted plates; and a shacklemoveably mounted around the leveling screw.

Box 1106 depicts the step of receiving hydraulic fluid from a reservoirthrough an input port fluidly to a pivoting hydraulic cylinder.

Box 1110 depicts the step of transferring the hydraulic fluid to thereservoir and output port from the pivoting hydraulic cylinder.

Box 1120 depicts the step of bidirectionally flowing the hydraulic fluidto and from the first pivoting hydraulic cylinder port through a firstbidirectional control port to and from the pivoting hydraulic cylinder.

Box 1130 depicts the step of bidirectionally flowing the hydraulic fluidto and from the second pivoting hydraulic cylinder port through a secondbidirectional control port to and from the pivoting hydraulic cylinder.

Box 1140 depicts the step of using a lever engaging a manifold to changehydraulic fluid flow rates to and from the pivoting hydraulic cylinder.

Box 1142 depicts the step of using a latching head connected to acylinder rod of the pivoting hydraulic cylinder and using the pivotingwrench enabling adjustment of the pivoting wrench to adjust a locationof the second segment of a connected multi-segment tubular segment.

Box 1150 depicts the step of adjusting a primary pressure control valveto adjust hydraulic fluid pressure to and from the pivoting hydrauliccylinder.

Box 1160 depicts the step of affixing the first pivoting wrench to afirst segment of a connected multi-segment tubular, and a stationarywrench to a second segment of a connected multi-segment tubular.

Box 1162 depicts the step of using a wrench stop to control pivoting ofthe wrenches to within a preset limit.

Box 1170 depicts the step of operating the hydraulic fluid to move thepivoting hydraulic cylinder to break out the first segment of aconnected multi-segment tubular from the second segment of a connectedmulti-segment tubular.

While these embodiments have been described with emphasis on theembodiments, it should be understood that within the scope of theappended claims, the embodiments might be practiced other than asspecifically described herein.

What is claimed is:
 1. A method for accelerated break out of connectedmulti-segment tubulars, the method comprising: a. using an acceleratedrod and sinker bar break out device with a support beam mounted inparallel to an installed pivoting hydraulic cylinder to prevent collapseof a base of the accelerated rod and sinker bar break out device; b.setting hydraulic fluid pressure in the accelerated rod and sinker barbreak out device to between 100 and 3000 psi; c. connecting a stationarywrench of the accelerated rod and sinker bar break out device to a firstsegment of a connected multi-segment tubular; d. connecting a pivotingwrench of the accelerated rod and sinker bar break out device to asecond segment of the connected multi-segment tubular; e. activating apivoting hydraulic cylinder of the accelerated rod and sinker bar breakout device using a lever to break out the first segment from the secondsegment, and wherein the pivoting wrench is configured to operate rightside up and upside down for optimizing pivoting wrench flat fit; andwherein the stationary wrench extends at an angle of 90 degrees to aplane of the base.
 2. The method of claim 1, comprising using an angledwrench head and a pivoting wrench anti as the pivoting wrench.
 3. Themethod of claim 1, comprising using an active radio frequencyidentification chip for tracking a GPS location of each accelerated rodand sinker bar break out device when deployed, and wherein the radiofrequency identification chip communicates via a network to at least oneclient device having a client device display and a client deviceprocessor communicating with computer instructions in a client devicedata storage instructing the client device processor to position the GPSlocation of the accelerated rod and sinker bar break out devicegeographically on a map.
 4. The method of claim 3, comprising using amicroprocessor connected to at least one pressure sensor forautomatically monitoring and comparing detected pressures to presetlimits stored in a microprocessor data storage, and computerinstructions for instructing the microprocessor to provide an alarm tothe client device processor via the network when the pressure fallsbelow or exceeds the preset limits.
 5. The method of claim 1, comprisingusing a hydraulic pressure from 100 psi to 3000 psi in a manifoldmounted to the accelerated rod and sinker bar break out device.
 6. Themethod of claim 1, comprising using a pivoting wrench and a stationarywrench each having a thickness from ½ of an inch to 1 inch.
 7. Themethod of claim 1, comprising using a pivoting wrench and the stationarywrench made from a hardened high tensile strength solid steel hardenedto a Rockwell 55 hardness, wherein each wrench is a pipe wrench.
 8. Themethod of claim 1, comprising using a pivoting wrench and a stationarywrench, each having a length from 18 inches to 48 inches.
 9. The methodof claim 1, comprising using a pivoting wrench with a head having alength different than the head of the stationary wrench.
 10. The methodof claim 1, comprising using a pivoting wrench with an arm having alength different than an arm of the stationary wrench.
 11. The method ofclaim 1, comprising using a stationary wrench with a hook shape to holdthe accelerated rod and sinker bar break out device stable as thepivoting wrench head is attached to the wrench flats of the connectedmulti-segment tubulars.
 12. A method for accelerated break out ofconnected multi-segment tubulars, the method comprising: a. receivinghydraulic fluid from a reservoir through an input port fluidly to apivoting hydraulic cylinder; b. transferring the hydraulic fluid to thereservoir an output port from the pivoting hydraulic cylinder; c.bidirectionally flowing the hydraulic fluid to and from the firstpivoting hydraulic cylinder port through a first bidirectional controlport to and from the pivoting hydraulic cylinder; d. bidirectionallyflowing the hydraulic fluid to and from the second pivoting hydrauliccylinder port through a second bidirectional control port to and fromthe pivoting hydraulic cylinder; e. using a lever engaging a manifold tochange hydraulic fluid flow rates to and from the pivoting hydrauliccylinder; f. adjusting a primary pressure control valve to adjusthydraulic fluid pressure to and from the pivoting hydraulic cylinder,and g. affixing the first pivoting wrench to a first segment of aconnected multi-segment tubular, and a stationary wrench to a secondsegment of a connected multi-segment tubular; and h. operating thehydraulic fluid to move the pivoting hydraulic cylinder to break out thefirst segment of a connected multi-segment tubular from the secondsegment of a connected multi-segment tubular.
 13. The method of claim12, comprising the step of using a flexible hanger and leveling devicefor stabilizing the equipment of the method as the method is implementedusing a pair of slotted plates mounted in parallel on a top side of ahousing holding components of utilized in the method and; a levelingscrew installed through slots of the pair of slotted plates; and ashackle moveably mounted around the leveling screw.
 14. The method ofclaim 1, comprising using a wrench stop to control pivoting of thewrenches to within a preset limit.
 15. The method of claim 1, comprisingusing a latching head connected to a cylinder rod of the pivotinghydraulic cylinder and using the pivoting wrench enabling adjustment ofthe pivoting wrench to adjust a location of the second segment of aconnected multi-segment tubular segment.